Current-Induced Evolving Mechanical Properties, Formation of Defects, and Interfacial Intermetallic Growth in the Interconnects Bonded with Au Wire

Xiaohong Yuan; Qinlian He; Xiaojing Wang; Jiaheng Zhang; Dapeng Yang; Qinsong Bi; Yuxi Luo; Dengquan Chen; Shanju Zheng; Manal S. Ebaid; Hassan Algadi; Zhanhu Guo

doi:10.1021/acsami.5c03751

Current-Induced Evolving Mechanical Properties, Formation of Defects, and Interfacial Intermetallic Growth in the Interconnects Bonded with Au Wire

Xiaohong Yuan^*, Qinlian He, Xiaojing Wang^*, Jiaheng Zhang, Dapeng Yang, Qinsong Bi, Yuxi Luo, Dengquan Chen, Shanju Zheng^*, Manal S. Ebaid, Hassan Algadi, Zhanhu Guo^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

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Abstract

Continuously improving chip integration and increasing packaging density increase the risk of performance degradation and electromigration (EM) failure on the bonding interface during electrical transmission. While EM failure, as a time-accumulated failure, is one core challenge of semiconductor reliability and is particularly severe in highly integrated chips. However, the polarity differences existing in commercial devices and the evolving polarity characteristics of microscale bonding interfaces have not been well addressed. Therefore, this study describes the polarity effects of EM in a commercial chip-end Au–Al system and reveals the evolution of intermetallic compound (IMC) growth at bonding interfaces under high-density currents. An EM simulation model is developed to jointly analyze the influence of current-induced polarity effects on the evolution of material migration and IMC growth together with experimental results. Specifically, under the influence of the polarity effect, the thickness of the anode IMC layer is approximately twice as thick as that of the cathode. The IMC thickness on both sides is much thicker than the center under the influence of the size effect. Unlike previous studies, the IMC at the commercial bonding interface is mainly the Al3Au8 phase in columnar crystal morphology and the α-AlAu4 phase in nanocrystalline morphology, with the former being mainly located in the middle region of the IMC layer, while the latter is mainly located in the edge region of the IMC layer. Due to the overgrowth of the IMC layer, the tensile mechanical properties of the interface are degraded, and the failure mode transforms from a single neck fracture to a predominant joint detachment. This study complements and improves the research framework of Au/Al interface IMC at commercial chip joints and lays a theoretical foundation for the development of semiconductor chips toward high integration, high density, and high reliability.

Original language	English
Pages (from-to)	37193–37205
Number of pages	13
Journal	ACS Applied Materials and Interfaces
Volume	17
Issue number	25
Early online date	13 Jun 2025
DOIs	https://doi.org/10.1021/acsami.5c03751
Publication status	Published - 25 Jun 2025

Keywords

wire bonding
Au−Al
electromigration
polarity effect
IMCs
mechanical properties

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yuan-et-al-2025-current-induced-evolving-mechanical-properties-formation-of-defects-and-interfacial-intermetallicFinal published version, 12.9 MBLicence: CC BY

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Yuan, X., He, Q., Wang, X., Zhang, J., Yang, D., Bi, Q., Luo, Y., Chen, D., Zheng, S., Ebaid, M. S., Algadi, H., & Guo, Z. (2025). Current-Induced Evolving Mechanical Properties, Formation of Defects, and Interfacial Intermetallic Growth in the Interconnects Bonded with Au Wire. ACS Applied Materials and Interfaces, 17(25), 37193–37205. https://doi.org/10.1021/acsami.5c03751

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title = "Current-Induced Evolving Mechanical Properties, Formation of Defects, and Interfacial Intermetallic Growth in the Interconnects Bonded with Au Wire",

abstract = "Continuously improving chip integration and increasing packaging density increase the risk of performance degradation and electromigration (EM) failure on the bonding interface during electrical transmission. While EM failure, as a time-accumulated failure, is one core challenge of semiconductor reliability and is particularly severe in highly integrated chips. However, the polarity differences existing in commercial devices and the evolving polarity characteristics of microscale bonding interfaces have not been well addressed. Therefore, this study describes the polarity effects of EM in a commercial chip-end Au–Al system and reveals the evolution of intermetallic compound (IMC) growth at bonding interfaces under high-density currents. An EM simulation model is developed to jointly analyze the influence of current-induced polarity effects on the evolution of material migration and IMC growth together with experimental results. Specifically, under the influence of the polarity effect, the thickness of the anode IMC layer is approximately twice as thick as that of the cathode. The IMC thickness on both sides is much thicker than the center under the influence of the size effect. Unlike previous studies, the IMC at the commercial bonding interface is mainly the Al3Au8 phase in columnar crystal morphology and the α-AlAu4 phase in nanocrystalline morphology, with the former being mainly located in the middle region of the IMC layer, while the latter is mainly located in the edge region of the IMC layer. Due to the overgrowth of the IMC layer, the tensile mechanical properties of the interface are degraded, and the failure mode transforms from a single neck fracture to a predominant joint detachment. This study complements and improves the research framework of Au/Al interface IMC at commercial chip joints and lays a theoretical foundation for the development of semiconductor chips toward high integration, high density, and high reliability.",

keywords = "wire bonding, Au−Al, electromigration, polarity effect, IMCs, mechanical properties",

author = "Xiaohong Yuan and Qinlian He and Xiaojing Wang and Jiaheng Zhang and Dapeng Yang and Qinsong Bi and Yuxi Luo and Dengquan Chen and Shanju Zheng and Ebaid, \{Manal S.\} and Hassan Algadi and Zhanhu Guo",

year = "2025",

month = jun,

day = "25",

doi = "10.1021/acsami.5c03751",

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volume = "17",

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journal = "ACS Applied Materials and Interfaces",

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Yuan, X, He, Q, Wang, X, Zhang, J, Yang, D, Bi, Q, Luo, Y, Chen, D, Zheng, S, Ebaid, MS, Algadi, H & Guo, Z 2025, 'Current-Induced Evolving Mechanical Properties, Formation of Defects, and Interfacial Intermetallic Growth in the Interconnects Bonded with Au Wire', ACS Applied Materials and Interfaces, vol. 17, no. 25, pp. 37193–37205. https://doi.org/10.1021/acsami.5c03751

TY - JOUR

T1 - Current-Induced Evolving Mechanical Properties, Formation of Defects, and Interfacial Intermetallic Growth in the Interconnects Bonded with Au Wire

AU - Yuan, Xiaohong

AU - He, Qinlian

AU - Wang, Xiaojing

AU - Zhang, Jiaheng

AU - Yang, Dapeng

AU - Bi, Qinsong

AU - Luo, Yuxi

AU - Chen, Dengquan

AU - Zheng, Shanju

AU - Ebaid, Manal S.

AU - Algadi, Hassan

AU - Guo, Zhanhu

PY - 2025/6/25

Y1 - 2025/6/25

N2 - Continuously improving chip integration and increasing packaging density increase the risk of performance degradation and electromigration (EM) failure on the bonding interface during electrical transmission. While EM failure, as a time-accumulated failure, is one core challenge of semiconductor reliability and is particularly severe in highly integrated chips. However, the polarity differences existing in commercial devices and the evolving polarity characteristics of microscale bonding interfaces have not been well addressed. Therefore, this study describes the polarity effects of EM in a commercial chip-end Au–Al system and reveals the evolution of intermetallic compound (IMC) growth at bonding interfaces under high-density currents. An EM simulation model is developed to jointly analyze the influence of current-induced polarity effects on the evolution of material migration and IMC growth together with experimental results. Specifically, under the influence of the polarity effect, the thickness of the anode IMC layer is approximately twice as thick as that of the cathode. The IMC thickness on both sides is much thicker than the center under the influence of the size effect. Unlike previous studies, the IMC at the commercial bonding interface is mainly the Al3Au8 phase in columnar crystal morphology and the α-AlAu4 phase in nanocrystalline morphology, with the former being mainly located in the middle region of the IMC layer, while the latter is mainly located in the edge region of the IMC layer. Due to the overgrowth of the IMC layer, the tensile mechanical properties of the interface are degraded, and the failure mode transforms from a single neck fracture to a predominant joint detachment. This study complements and improves the research framework of Au/Al interface IMC at commercial chip joints and lays a theoretical foundation for the development of semiconductor chips toward high integration, high density, and high reliability.

AB - Continuously improving chip integration and increasing packaging density increase the risk of performance degradation and electromigration (EM) failure on the bonding interface during electrical transmission. While EM failure, as a time-accumulated failure, is one core challenge of semiconductor reliability and is particularly severe in highly integrated chips. However, the polarity differences existing in commercial devices and the evolving polarity characteristics of microscale bonding interfaces have not been well addressed. Therefore, this study describes the polarity effects of EM in a commercial chip-end Au–Al system and reveals the evolution of intermetallic compound (IMC) growth at bonding interfaces under high-density currents. An EM simulation model is developed to jointly analyze the influence of current-induced polarity effects on the evolution of material migration and IMC growth together with experimental results. Specifically, under the influence of the polarity effect, the thickness of the anode IMC layer is approximately twice as thick as that of the cathode. The IMC thickness on both sides is much thicker than the center under the influence of the size effect. Unlike previous studies, the IMC at the commercial bonding interface is mainly the Al3Au8 phase in columnar crystal morphology and the α-AlAu4 phase in nanocrystalline morphology, with the former being mainly located in the middle region of the IMC layer, while the latter is mainly located in the edge region of the IMC layer. Due to the overgrowth of the IMC layer, the tensile mechanical properties of the interface are degraded, and the failure mode transforms from a single neck fracture to a predominant joint detachment. This study complements and improves the research framework of Au/Al interface IMC at commercial chip joints and lays a theoretical foundation for the development of semiconductor chips toward high integration, high density, and high reliability.

KW - wire bonding

KW - Au−Al

KW - electromigration

KW - polarity effect

KW - IMCs

KW - mechanical properties

UR - https://www.scopus.com/pages/publications/105008383663

U2 - 10.1021/acsami.5c03751

DO - 10.1021/acsami.5c03751

M3 - Article

C2 - 40511769

SN - 1944-8244

VL - 17

SP - 37193

EP - 37205

JO - ACS Applied Materials and Interfaces

JF - ACS Applied Materials and Interfaces

IS - 25

ER -

Current-Induced Evolving Mechanical Properties, Formation of Defects, and Interfacial Intermetallic Growth in the Interconnects Bonded with Au Wire

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Keywords

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